收藏本站
参数资料
型号: MIC2594-2BM TR
厂商: Micrel Inc
文件页数: 16/21页
文件大小: 1079K
描述: IC CTRLR HOT SWAP NEG HV 8-SOIC
标准包装: 2,500
类型: 热交换控制器
应用: 通用
内部开关:
电源电压: -19 V ~ -80 V
工作温度: -40°C ~ 85°C
安装类型: 表面贴装
封装/外壳: 8-SOIC(0.154",3.90mm 宽)
供应商设备封装: 8-SOIC
包装: 带卷 (TR)
其它名称: MIC2594-2BMTR
MIC2594-2BMTR-ND
September 2005
16
M9999-083005
MIC2588/MIC2594
Micrel
the drain-source breakdown voltage of the MOSFET must
be greater than V
IN(MAX)
, or V
DD
  V
EE
(min).
The second breakdown voltage criterion that must be met
is the gate-source voltage. For the MIC2588/MIC2594, the
gate of the external MOSFET is driven up to a maximum of
11V above VEE. This means that the external MOSFET must
be chosen to have a gate-source breakdown voltage of 12V
or more; 20V is recommended. Most power MOSFETs with
a 20V gate-source voltage rating have a 30V drain-source
breakdown rating or higher. For many 48V telecom applica-
tions, transient voltage spikes can approach, and sometimes
exceed, 100V. The absolute maximum input voltage rating
of the MIC2588/MIC2594 is 100V; therefore, a drain-source
breakdown voltage of 100V is suggested for the external
MOSFET. Additionally, an external input voltage clamp is
strongly recommended for applications that do not utilize
conditioned power supplies.
Power MOSFET Steady-State Thermal Issues
The selection of a MOSFET to meet the maximum continuous
current is a fairly straightforward exercise. First, arm yourself
with the following data:
"The value of I
LOAD(CONT, MAX.)
 for the output in question
(see Sense Resistor Selection).
"The manufacturers datasheet for the candidate MOS-
FET.
"The maximum ambient temperature in which the device
will be required to operate.
"Any knowledge you can get about the heat sinking avail-
able to the device (e.g., can heat be dissipated into the
ground plane or power plane, if using a surface-mount
part? Is any airow available?).
The datasheet will almost always give a value of on resistance
for a given MOSFET at a gate-source voltage of 4.5V and
10V. For MIC2588/MIC2594 applications, choose the gate-
source ON resistance at 10V and call this value R
ON
. Since
a heavily enhanced MOSFET acts as an ohmic (resistive)
device, almost all thats required to determine steady-state
power dissipation is to calculate I
2
R. The one addendum to
this is that MOSFETs have a slight increase in R
ON
 with in-
creasing die temperature. A good approximation for this value
is 0.5% increase in R
ON
 per 癈 rise in junction temperature
above the point at which R
ON
 was initially specied by the
manufacturer. For instance, if the selected MOSFET has a
calculated R
ON
 of 10m& at aT
J
 = 25癈, and the actual junc-
tion temperature ends up at 110癈, a good rst cut at the
operating value for R
ON
would be:
R
ON
 H 10m&[1 + (110  25)(0.005)] H14.3m&
The nal step is to make sure that the heat sinking available
to the MOSFET is capable of dissipating at least as much
power (rated in 癈/W) as that with which the MOSFETs
performance was specied by the manufacturer. Here are
a few practical tips:
1. The heat from a TO-263 power MOSFET ows
almost entirely out of the drain tab. If the drain tab
can be soldered down to one square inch or more,
the copper will act as the heat sink for the part. This
copper must be on the same layer of the board as
the MOSFET drain.
2. Airow works. Even a few LFM (linear feet per-
minute) of air will cool a MOSFET down substan-
tially. If you can, position the MOSFET(s) near
the inlet of a power supplys fan, or the outlet of a
processors cooling fan.
3. The best test of a candidate MOSFET for an ap-
plication (assuming the above tips show it to be a
likely t) is an empirical one. Check the MOSFETs
temperature in the actual layout of the expected
nal circuit, at full operating current. The use of a
thermocouple on the drain leads, or infrared pyrom-
eter on the package, will then give a reasonable
idea of the devices junction temperature.
Power MOSFET Transient Thermal Issues
If the prospecitve MOSFET has been shown to withstand the
environmental voltage stresses and the worse-case steady-
state power dissipation is addressed, the remaining task is to
verify if the MOSFET is capable of handling extreme overcur-
rent load faults, such as a short circuit, without overheating.
A power MOSFET can handle a much higher pulsed power
without damage than its continuos power dissipation ratings
imply due to an inherent trait, thermal inertia. With respect to
the specication and use of power MOSFETs, the parameter
of interest is the Transient Thermal Impedence, or Z
?/DIV>
, which
is a real number (variable factor) used as a multiplier of the
thermal resistance (R
?/DIV>
). The multiplier is determined using
the given Transient Thermal Imepedence Graph, normalized
to R
?/DIV>
, that displays curves for the thermal impedence versus
power pulse duration and duty cycle. The single-pulse curve
is appropriate for most hot swap applications. Z
?/DIV>
 is specied
from junction-to-case for power MOSFETs typically used in
telecom applications.
The following example provides a method for estimating the
peak junction temperature of a power MOSFET in determin-
ing if the MOSFET is suitable for a particular application.
V
IN
 (VDD  VEE) = 48V, I
LIM
 = 4.2A, and the power MOSFET
is SUM110N10-09 (TO-263 package) from Vishay-Siliconix.
This MOSFET has an R
ON
 of 9.5m& (T
J
 = 25癈), the junc-
tion-to-case thermal resistance (R
?J-C)
) is 0.4癈/W, junc-
tion-to-ambient thermal resistance (R
?J-A)
) is 40癈/W, and
the Transient Thermal Impedence Curve is shown in Figure
7. Consider, say, the MOSFET is switched on at time t1 and
the steady-state load current passing through the MOSFET
is 3A. At some point in time after t1, at time t2, there is an
unexpected short-circuit applied to the load, causing the
MIC2588/MIC2594 controller to adjust the GATE output
voltage and regulate the load current for 400祍 at the pro-
grammed current limit value, 4.2A in this example. During this
short-circuit load condition, the dissipation in the MOSFET
is calculated by:
P
D
(short) = V
DS
 ?I
LIM
 
V
DS
 = 0V  (-48V) = 48V
P
D
(short) = 48V ?4.2A = 201.6W for 400祍.
At rst glance, it would appear that a very hefty MOSFET is
required to withstand this extreme overload condition. Upon
further examination, the calculation to approximate the peak
junction temperature is not a difcult task. The rst step is to
determine the maximum steady-state junction temperature,
相关PDF资料
PDF描述
MIC2595R-2BM TR IC CTRLR HOT SWAP NEG HV 14-SOIC
MIC280-7BM6 TR IC SUPERVISOR THERMAL SOT23-6
MIC2800-GFSYML TR IC REG TRPL BUCK/LINEAR 16MLF
MIC281-7BM6 TR IC SUPERVISOR THERMAL SOT23-6
MIC2810-1JGMYML TR IC REG TRPL BUCK/LINEAR 16MLF
相关代理商/技术参数
参数描述
MIC2594-2YM 功能描述:热插拔功率分布 Negative Voltage Hot-Swap Controller - Lead Free RoHS:否 制造商:Texas Instruments 产品:Controllers & Switches 电流限制: 电源电压-最大:7 V 电源电压-最小:- 0.3 V 工作温度范围: 功率耗散: 安装风格:SMD/SMT 封装 / 箱体:MSOP-8 封装:Tube
MIC2594-2YM TR 功能描述:热插拔功率分布 Negative Voltage Hot-Swap Controller - Lead Free RoHS:否 制造商:Texas Instruments 产品:Controllers & Switches 电流限制: 电源电压-最大:7 V 电源电压-最小:- 0.3 V 工作温度范围: 功率耗散: 安装风格:SMD/SMT 封装 / 箱体:MSOP-8 封装:Tube
MIC2594-2YM-TR 功能描述:Hot Swap Controller 1 Channel -48V 8-SOIC 制造商:microchip technology 系列:- 包装:剪切带(CT) 零件状态:停产 类型:热交换控制器 通道数:1 内部开关:无 应用:-48V 特性:故障超时,闭锁故障 可编程特性:限流,压摆率,UVLO 电压 - 电源:-80 V ~ -19 V 电流 - 输出(最大值):- 工作温度:-40°C ~ 85°C 电流 - 电源:3mA 安装类型:表面贴装 封装/外壳:8-SOIC(0.154",3.90mm 宽) 供应商器件封装:8-SOIC 功能引脚:DRAIN,OFF,ON,/PWRGD 标准包装:1
MIC2595-1BM 功能描述:IC CTRLR HOT SWAP NEG HV 14-SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - 热交换 系列:- 产品培训模块:Obsolescence Mitigation Program 标准包装:100 系列:- 类型:热插拔开关 应用:通用 内部开关:是 电流限制:可调 电源电压:9 V ~ 13.2 V 工作温度:-40°C ~ 150°C 安装类型:表面贴装 封装/外壳:10-WFDFN 裸露焊盘 供应商设备封装:10-TDFN-EP(3x3) 包装:管件
MIC2595-1BM TR 功能描述:IC CTRLR HOT SWAP NEG HV 14-SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - 热交换 系列:- 产品培训模块:Obsolescence Mitigation Program 标准包装:100 系列:- 类型:热插拔开关 应用:通用 内部开关:是 电流限制:可调 电源电压:9 V ~ 13.2 V 工作温度:-40°C ~ 150°C 安装类型:表面贴装 封装/外壳:10-WFDFN 裸露焊盘 供应商设备封装:10-TDFN-EP(3x3) 包装:管件
发布紧急采购,3分钟左右您将得到回复。

采购需求

(若只采购一条型号,填写一行即可)

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

*型号 *数量 厂商 批号 封装
添加更多采购

我的联系方式

*
*
*